Self-adaptive Metal-Organic Framework Assembles Di-iron Active Sites to Mimic Monooxygenases.

Despite significant efforts, it remains a challenge to design artificial enzymes that can mimic both structures and functions of natural enzymes. Here, we report the post-synthetic construction of binuclear iron catalysts in MOF-253 to mimic natural di-iron monooxygenases. The adjacent bipyridyl (bpy) linkers in MOF-253 can freely rotate to form the [(bpy)Fe III (μ 2 -OH)] 2 active site in a self-adaptive fashion. The composition and structure of the [(bpy)Fe III (μ 2 -OH)] 2 active sites in MOF-253 were characterized by a combination of inductively coupled plasma-mass spectrometry, thermogravimetric analysis, X-ray absorption spectrometry, and Fourier-transform infrared spectroscopy. The MOF-based artificial monooxygenase effectively catalyzed oxidative transformations of organic compounds, including C-H oxidation and alkene epoxidation reactions, using O 2 as the only oxidant, which indicates the successful recapitulation of the structure and functions of natural monooxygenases using readily accessible MOFs. The di-iron system exhibited at least 27 times higher catalytic activity than the corresponding mononuclear control. DFT calculations showed that the binuclear system had a 14.2 kcal/mol lower energy barrier than the mononuclear system in the rate-determining C-H activation process, suggesting the importance of cooperativity of the iron centers in the [(bpy)Fe III (μ 2 -OH)] 2 active site in the rate-determining step. The stability and recyclability of the MOF-based artificial monooxygenase were also demonstrated.